Method of building reinforced tire construction



March 18, 1969 A. MARZOCCHI E AL 3,433,689 I METHOD OF BUILDING RE IIIIIIIIIIIIIIIIIIIIII ON 1 INVENTORS 44 FFE'D MAAZfiCC/l/ & BY 41mm W/A/sal? Awm/ March 18, 1969 A. MARZOCCH! ET L 3,433,689

METHOD OF BUILDING REINFORCED TIRE CONSTRUCTION Original Filed April 26, 1965 Sheet 3 INVENTORS 4.4 mm MAFZUCCH/ &

March 18, 1969 MARZQCCHI ET AL j 3,433,689

METHOD OF BUILDING REINFORCED TIRE CONSTRUCTION Original Filed April 26, 1965 Sheet 4 of 5 March 18, 1969 A. MARZOCCHI ET AL METHOD OF BUILDING REINFORCED TIRE CONSTRUCTION Sheet Original Filed April 26, 1965 United States Patent Ofiice 3,433,689 Patented Mar. 18, 1969 3,433,689 METHOD OF BUILDING REINFORCED TIRE CONSTRUCTION Alfred Marzocchi, Cumberland, and Alfred Wiusor Brown, Woonsocket, R.I., assignors to Owens- Corning Fiberglas Corporation, a corporation of Delaware Original application Apr. 26, 1965, Ser. No. 450,790, now Patent No. 3,315,722, dated Apr. 25, 1967. Divided and this application Mar. 13, 1967, Ser. No. 622,588 U.S. Cl. 15696 30 Claims Int. Cl. B29h 17/10, 17/37 ABSTRACT OF THE DISCLOSURE Tire building process, including retreading operations, wherein a reinforcement in the form of an elastomeric band containing chopped glass or a continuous cord composed of a plurality of gathered together filaments of glass is wrapped about the carcass before the application of the tread. The cord may additionally include other fibrous materials.

This application is a division of application Ser. No. 450,790, filed April 26, 1965, now U.S. Patent No. 3,315,722.

The present invention relates to pneumatic tires and, in particular, to methods of manufacturing tires to include novel reinforcement members.

Over the years, a number of textile materials have been employed as reinforcement components in tire constructions. The earliest tires employed cotton in the form of a fabric; more recently, in the form of bias cut, mutually parallel cords. More recently, tire manufacturers employed rayon and currently employ nylon as a reinforcing textile. In recent years, polyester, e.g., Dacron, fibers, yarns and strands, and even wire cords, have entered the picture; each contributing its own particular features of advantage. Glass fiber have also been suggested as a reinforcing component for tires. See, for example, the following U.S. Patents 2,184,326, 2,884,040 and 2,894,555.

Many of the textiles mentioned above, in addition to having their inherent advantages, have accompanying disadvantages. Cotton is deficient due to the inherent propensity to undergo moisture degradation. Rayon is not much stronger, is low in modulus and, in addition, is undesirable in certain respects because of its low strength per unit cross sectional area.

Nylon has found considerable acceptance by reason of its increased strength as compared to rayon, coupled with its toughness and high impact resistance which makes it extremely desirable in providing a tough carcass capable of withstanding considerable abuse. Another advantage of using fabric plies composed of synthetic linear filaments such as nylon entire casings is that the filaments of nylon have a high tensile strength which makes it practical to manufacture heavy duty tires with relatively thin ,side walls and yet of relatively light weight, whereby less rubber is required and less heat is developed in actual case. Polyester as a reinforcing medium is not fully evaluated as yet, but appears to present some promise as a tire reinforcement.

Nylon, with all of its advantages, is possessed of at least one serious drawback by reason of its thermal character. Thus, nylon fabric, e.g., the nylon cords, tend to progressively and permanently become elongated when the tire is in service due to tension stresses to which the cords are subjected and the heat generated in the tire running under load. This characteristic of nylon cord causes the tire casings to increase in size, which sets up stresses in the treads which cause cracks to develop in the treads, greatly reducing the resistance of the treadto wear. Another ramification of the foregoing is the tendency of the nylon fabric reinforced tire to thump due to so-called fiat spotting. This is generally evidenced to the user by the fact that, after parking overnight, the tire cord will, due to the normal temperaturedrop, become heat set in a somewhat flattened contour caused by the depression on the bottom of the tire in contact with the pavement. This fiat spot causes a noticeable thump when the car is run again, which albeit gradually disappears as heat is developed due to the load on the tire and the operational speed. This particular phenomena has been greatly credited with the failure of nylon cord tires to be utilized by automobile manufacturers as original equipment.

Conventional fabrics used heretofore are also posessed of the drawback that tires, regardless of the care taken in manufacture, are of irreproducible constant diameter. This is to say that tires produced in different factories, even though utilizing the same specification, fabrics, rubber stock, building techniques and cure cycles, will rarely have the same overall dimension. Tires made with conventional fabrics plies are also found to experience variable change in dimensions after a given period of road use. This is particularly undesirable in the field of truck tires, since such tires are desirably retreaded. As a consequence, tires to be mounted on dual wheels must be individually paired by the user according to size in order to get an even match which will give satisfactory performance.

Conventional fabric (rayon, nylon, etc.), reinforced tires of the bias type are generally not as stable as would be desired, particularly on cornering. This lack of cornering stability resides in the conventional technique practiced in the design of tires generally. Thus, it is conventional in U.S. tire manufacturing, to design the carcass construction [composed of a plurality of overlying bias plies], the tread, the side wall and the beads in such fashion that the whole structure functions integrally to define the optimum in wear properties of the tire. Under these design conditions, cornering stability of the tire suffers somewhat. On the other hand, tires of the Michelin type, employing radial cords with a reinforcing wire breaker strip just beneath the tread portion, provide a stability which is greater than tires of the bias type. However, this is accomplished only at a sacrifice in smoothness of ride, e.g., the ride is harsher.

Bias tires employing the conventional fabrics are also beset with the problem of tread movement or squirming as to that portion in contact with the road surface. This frequently results in the tread definition becoming dis torted into a configuration inconsistent with that for which tread definition was designed.

With the foregoing general introduction, it may be stated that it is a general object of the present invention to provide a reinforcement system for pneumatic tires which provides features of advantage which in large measure overcome the drawbacks and deficiencies noted hereinabove.

It is another object of the present invention to provide a tire construction employing features of reinforcement which are novel, but yet readily adaptable into conventional tire manufacturing facilities.

It is yet another object of the present invention to pro vide a system of tire reinforcement which lends a happy marriage between improved wear, minimized flat spotting or thump and improved cornering properties.

It may be stated here parenthetically that stability is also evidenced in a tire in terms of a uniform footprint, as it were. In conventional tire constructions employing bias cut ply reinforcement, the footprint of the tire, that is, the contour defined by the surface of the tire in contact with the road, varies considerably as the tire rolls along the pavement. Much of this, of course, is due to the variation in load due to imperfections in the road surface, valleys and crests of the roads, cracks in the road, foreign objects, etc., which all serve to shift the load. On the other hand, what is more important is the character of the footprint as the tire corners, as it were. Here, a variation in the area of contact, in effect, changes the dynamic relationship of the center of gravity of the automobile and the road. This phenomenon explains why skids occur on cornering, resulting in accidents. Thus, the contour of the footprint changes, particularly in inclement weather, moisture, wet roads, damp roads, etc. Ideally, on cornering, the footprint should remain the same; namely, describing a generally square outline or, in any event, of rectangular contour. Where one of the sides of the footprint becomes curvilinear, for example, by the way of opposed intersecting catenary curves, then an unstable condition exists which can prove uncomfortable and even disastrous to the driver, depending upon the speed of the vehicle, the weight of the vehicle and, of course, the condition of the pavement. etc.

It is a particular object of the present invention to provide a reinforcement technique which minimizes the tendency to experience thermal set which is usually inherent in nylon cord reinforced tires.

It is additionally an object of the present invention to provide a method of building a tire which permits the production of tires of relatively uniform size and additionally results in a tire which retains uniform overall dimensions even after prolonged use.

It is still another object of the present invention to provide a method of building a tire which permits the production of tires having the above-enumerated advantages.

It is additionally an object of the present invention to provide a method of retreading tires, particularly of the off-the-road type or the aircraft type, wherein retreading is of considerable economic importance, having in mind the rigorous applications, endurance and related problems which such tires must endure. Aircraft tires, of course, must endure rigorous punishment in absorbing the tremendous load of the aircraft upon landing. Additionally, such tires must be capable of enduring high speed and contact with foreign objects on the runway. All of these place a considerable burden upon the tread. On the other hand, the side wall remains relatively unharmed so that it becomes economically expedient for such tires to be retreaded. By the present invention, we provide a convenient and practical method of retreading which includes a system for reinforcing the tire and additionally protecting it against penetration by foreign objects such as nails, bolts, nuts and other foreign objects likely to be encountered on the average airstrip.

The foregoing, as well as other objects of the present invention, will become apparent to those skilled in the art from the following detailed description taken in conjunction with the annexed sheets of drawings on which there are presented, for purposes of illustration only, several embodiments of the present invention.

The invention will be described in greater detail with particular reference to the annexed sheets of drawings in which:

FIG. 1 is a generally three-quarter perspective view of a tire with the outer rubber ply broken away for purposes of showing the interior reinforcing construction representing a preferred embodiment of the present invention;

FIG. 2 is a view similar to FIG. 1, showing an alternative construction in accordance with another embodiment of the present invention;

FIG. 3 is a perspective view with a portion broken away, but showing a reinforcing band or belt representing a component of the reinforcement system illustrated in FIGS. 1- a d 2;

FIG. 4 is a view similar to FIG. 3, but showing a modified construction of the reinforcing band in accordance with another embodiment of the present invention;

FIG. 5 is a view similar to FIGS. 3 and 4, but showing yet another alternative variant construction in accordance with yet another embodiment of the present invention;

FIG. 6 is a schematic side elevational view illustrating a manner of performing one method in accordance with the present invention;

FIG. 7 is a top plan view of the apparatus schematically illustrated in FIG. 6;

FIG. 8 is a perspective view of a particular cord construction constituting an assembly of strands composed of different filaments as representing a variant embodiment of the reinforcing system for pneumatic tires in accordance with the present invention;

FIG. 9 is a perspective view similar to FIGS. 1 and 2 and illustrating an alternative construction embodying a reinforcing system in accordance with another embodiment of the present invention; and

FIG. 10 is a schematic side elevational view illustrating one manner of assembling a restrictive band construction representing one embodiment of the present invention.

In its simplest embodiment, the present invention envisions a tire construction employing a restricting and/ or reinforcing band located between the carcass plies and the tread and peripherally encircling the tire; the band being of a particularly specified construction employing the combination of individual, short filaments of glass fiber uniformly distributed throughout the band and, additionally, a plurality of individual lengths of cords of glass fiber relatively uniformly distributed throughout the band.

More specifically, the present invention envisions a tire construction employing bias cut plies of nylon cord and having a circumferential restricting band of elastomcric stock located peripherally about one or more of the nylon plies; said band having embedded therein a plurality of mutually parallel cords, bundles and/or strands of continuous substantially inextensible material, e.g., glass, and also including short lengths of glass filaments.

At this point, definition of terms appears in order.

A filament of glass is an individual fiber or solid rod, as it were. A strand, on the other hand, is a collection of a great plurality of individual filaments, usually varying from a grouping numbering in the neighborhood of 104, 208, and even up to 508-2000 individual filaments gathered together in a manner well known in the art and technology of glass fiber manufacture.

A cord, bundle or cable, on the other hand, comprises a plurality of strands, for example, 2 to 30, and even up to 50 strands, plied or assembled together continuously. The strands may be possessed of twist, reverse twist, or no twist. Further, a number of strands of several ply constructions, e.g., 3 strands, may be combined to yield an ultimate cord having a total number of strands equal to the product of the number of strands in the first assembly and the number of these assemblies that are combined to make up the final cord. As can be appreciated, a cord will be composed of a large number of individual filaments, say in the neighborhood of 300 to 2000. By way of illustration, a cord construction may feature 3 strands of continuous filaments gathered together with or without twist. Additionally, 10 of the justforegoing 3-ply strand assemblies may be joined together with or without twist to form, in effect, a 30-strand assembly; each strand being composed, for example, of perhaps to 200 filaments yielding a 3000 to 6000 filament cord, cable or bundle assembly. A 30,000 filament assembly cord is achieved by (l) forming a 10- strand assembly; (2) combining 5 of these to form a 50- strand assembly; and (3) finally combining 3 of the latter to yield a ISO-strand cord. The cord designation for the latter is 5/ 3.

The present invention envisions a restrictive band featuring the employment of an elastomeric stock system which includes therein both filamentized short lengths of glass fibers and, additionally, unfilamentized or unseparated bundles or cords of glass fibers. Most desirably, the reinforcing fibers and cords are selected of a given range of lengths. It is additionally envisioned that the elastomeric stock system, forming a restrictive band in accordance with the present invention, may contain continuous mutually parallel lengths of strands or cords separated one from the other and perhaps proceeding in spiral fashion or filament-wound fashion about the periphery of the tire radially outwardly of the reinforcement fabric, yet beneath the tread portion. In some cases, the continuous strands are arranged so that they extend into the tread portion where such would be desirable.

To illustrate the potentiality of glass fiber as a reinforcing component of tires in dynamic application, the properties of a single filament of glass fiber are listed in Table I.

TABLE I.GLASS FIBER SINGLE FILAMENT PROPERTIES Tensile strength, p.s.i 500,000 Tenacity, g.p.d 15.3 Ultimate elongation, percent 4.8 Elastic recovery, percent 100 Toughness, p.s.i 11,900

Modulus, p.s.i 10,500,000

Coefficient of thermal expansion, F. 2.8 10-- Water adsorbency, percent 0.3 Moisture regain, percent 0.0

while the glass fibers in the form of fibers, strands, cords or bundles can be introduced into the elastomeric stock as'is, so to speak, it is most effective for the glass fibers to be first treated or sized, as it were, to provide a protection against interfilament destructive action. This can be overcome by a combination of treatments to provide a protective coating as Well as a bonding and anchoring agent on the surface which will enhance the bonding between the glass fiber surface and the elastomeric material. This is usually accomplished by a combination of sprayedon liquid size treatments just after the glass filament is formed and a subsequent impregnation of the strands or cords as they are formed, usually simply by introducing the gathered filaments into a pool of the treating liquid While simultaneously distorting the strand filaments to effect penetration into the zones between fibers, thereby insuring complete impregnation. Following impregnation, the coated strands or cords are given a mild heat treatment to set the treating agent. A system of treatment for glass fibers may involve a first surface treatment embodying an anchoring agent which enhances the bonding relationship between the glass fiber surface and the ultimately used elastomeric material. A suitable anchoring agent is represented by the amino silanes such as gamma-aminopropyltriethoxy silane or by a similar silane having a carboxyl group in the organic group attached to the silicon atom or an amino or carboxyl group in the carboxylate group of a Werner complex compound. These may be applied to the glass fiber surfaces or incorporated as a component of a size composition and applied to the glass fibers as they are gathered together in the formation of strands, yarns or the like; all of which is more fully described in the copending application Ser. No. 406,501, filed Oct. 26, 1964, entitled Glass Fibers Treated for Combination With Elastomeric Materials and Method, now US. Patent No. 3,391,052. A desired strong bonding relationship can also be achieved by the impregnation of the strands or other multi-filament glass fiber structure with a composition formulated to contain, in addition, an elastomeric material, preferably in an uncured or an unvulcanized state as described in the aforesaid copending appli- TABLE II.REINFORCEMENT CORD PROPERTIES, GLASS FIBERS VERSUS ORGANIC CORDS Glass Rayon Nylon Polyfibers ester Strength (p.s.i.) 407,000 94,000 122,000 104, 000

Toughness (p.s.i.) 9, 900 5, 800 10, 200 9, 900 Impact resistance,

ft. lbs. XlO-Idenier 3. 1. 87 4. 08 3. 41

Modulus, p.s.iXlO- r 8. 45 0. 96 0. 63 0. 57

Elongation, percent 4. 8 9.8 19. 3 18. 5

The properties appearing in the foregoing Table II speak generally for themselves. They generally demonstrate the toughness and impact strength of glass fiber cords. This, coupled with their high dimensional stability, demonstrates their great utility. Additionally, this, coupled with their relatively inert character to temperature or humidity changes, makes them a desirable and, in fact, an ideal tire reinforcement material when used in the manner disclosed herein. The problem, of course, has been in converting the well-known static properties of glass fibers into a construction which would endure dynamic stresses. The present invention solves this dilemma by reason of the novel conjoint employment of filamentized short length filaments, unseparated chopped bundles, strands or cords and, in a preferred embodiment, employment in the same band of elastomeric stock of mutually parallel strands, cords or bundles of a continuous nature.

The following are representative of size compositions which may be applied to the glass fibers in forming.

EXAMPLE 1 Percent by wt. Gamma-aminopropyltriethoxysilane Percent by wt.

Saturated polyester resin 3.2 Polargonate amide solubilized with acetic acid 0.1 Tetraethylene pentamine stearic acid 0.1 Polyvinyl alcohol 0.1 Polyvinyl pyrrolidone 3.0 Gamma-aminopropyltriethoxysilane 0.3 Acetic acid 0.1 Water 93.1

The size composition is merely applied to the glass fi ber filaments as they are gathered together and the strand of sized glass fibers is allowed to dry in ambient air.

In the foregoing examples, the gamma-aminopropyltriethoxysilane can be replaced as an anchoring agent with other aminosilanes such as gamma-aminopropylvinyldiethoxysilane, n gamma-triethoxysilylpropyl propylamine, beta-aminoalklyltriethoxysilane, aniline silane derivatives, etc.

While it is not essential to impregnate the strand or bundle of glass fibers before cutting or chopping tothe lengths desired for admixture with the-elastomeric material in forming the molding compound, it is preferred to impregnate the bundle of glass fibers for fuller separation of the fibers one from the other in the bundle and to incorporate an elastomeric system into the interior of the glass fiber bundle whereby the fibers can more effectively become anchored in the elastomeric system.

EXAMPLE 4 Parts by wt. Neoprene rubber 100 Powdered magnesium oxide 4 Powdered zinc oxide 5 Channel Black Thiate B (trialkyl thiourea accelerator) 1 The above ingredients after being mixed on a mill are combined with sufficient of an appropriate rubber solvent to form a liquid impregnant lbath.

EXAMPLE 5 Parts by wt. Paracril C ru bber (Buna N) 100 SRF carbon black Powdered zinc oxide 5 Aminox (reaction product of diphenyl amine ester) 0.5 Stearic acid 1 Dicumyl peroxide 40 The above ingredients after being mixed on a mill are combined with sufiicient of an appropriate rubber solvent to form a liquid impregnant bath.

EXAMPLE 6 Parts by wt. Lotol 5440, US. Rubber Company, Lotol 5440 is a 38% dispersed solids system including a butadienestyrene-vinylpyridine terpolymer latex, a butadienestyrene latex and a resorcinol-formaldehyde resin 60 Water 39 EXAMPLE 7 Parts by wt. Resorcinol formaldehyde resin 2 Formalin (37% solution) 1 Concentrated ammonium hydroxide 2.7 Vinylpyridine terpolymer (42% latex) 25 Neoprene rubber latex (50% solids) 41 Butadiene latex (60% solids) 5 Sodium hydroxide .05 Gamma-aminopropyltriethoxysilane 1 Vulcanizing agent 1 Water 1100 The impregnated cord or strand may be chopped to different sized lengths and thence incorporated into the elastomeric stock material in order to produce the vulcanizable restrictive band referred to earlier herein. Any type of commercial cutter may be employed to automatically cut the strands into lengths ranging from /3 to 3 inches in length. One cutter which has been utilized is called a Brenner cutter and is manufactured by Brenner Machine Company of Newark, Ohio. Another suitable cutter is manufactured by Turner Machine Company of Danbury, Conn.

To produce a glass reinforced elastomeric system in accordance with the present invention, a conventional rubber formulation, e.g., recipe, is introduced onto a mill and worked to a proper workable viscosity; care being taken not to scorch the elastomeric stock material. Then, 2 parts per hundred parts of rubber [hereinafter referred to as phr.] of treated impregnated glass cords or strands are gradually introduced to the mill which is set with the roll surfaces spaced apart about 0.055 inch. The stock on the mill is repeatedly cut and crossed to work the glass fiber such that the bundles or strands separate into individual filaments and thereby become intimately and homogeneously diffused throughout the mass. Next, anywhere from 5 to 75 phr. of additional lengths of chopped impregnated cord having a length of about A to 3 inches are introduced to the mill at the same setting or slightly smaller setting ranging down to 0.035 inch. When this addition has been completed, the material is allowed to stay on the mill for only a couple passes so that the bundles, strands or cords do not become separated into individual filaments, but substantially retain their bundle or cord identity. The material is then removed from the mill and cut to a bandwidth, generally corresponding to the shoulder to shoulder dimension of the tire to which it is to be affixed. The band width on examination will be found to contain both individual filaments of glass ranging from A to inch in length and lengths of strand or cord assemblies measuring from A to 3 inches in length. The short lengths of individual filaments result from the working and breaking up of the initial addition of 2 phr. of glass bundles. A band, as just described, is circumferentially wrapped about a nylon cord carcass ply construction on a tire building machine just prior to application of the tread stock strip. The mating edges can be chamfered in accordance with routine practice and the lateral edges can also be biased or feathered for smooth incorporation into the tire construction. Thereafter, the tire construction proceeds with the arrangement of the tread stock, setting of the beads and finally the vulcanization of the tire, yielding a finished tire embodying the present invention.

Referring now more particularly to the drawings, there is shown in FIG. 1 a tire 11 composed of spaced parallel circular bead wires 13 and 15 connected by the carcass portion 17 extending in torroidal configuration from one bead to the other. The beads are adapted to engage spaced rim flanges (not shown) on a vehicle wheel. The tire includes an outer peripheral tread portion 19 which serves as the ground contacting component of the tire. From the inside out, the carcass is (composed of an inner cushion ply 21 extending from head to bead and successively plies 22, 24, 26 and 28 of bias cut nylon fabric in which the principal cords C and C are mutually parallel with the same cords in the same ply and are at an acute angle to the peripheral center line 29 of the tire which is coincident with the peripheral rolling axis of the tire. The cords C in the carcass plies 22 and 26 describe the same angle, while the cords C in carcass plies 24 and 28 define an angle opposite to that of the cords C. The alternate reverse arrangement of the bias cut plies lends dynamic stability to the tire carcass considered as a whole. The carcass plies extend from head to head and then are wrapped reversely to extend up into the side wall, as generally indicated by the reference numeral 30. The ply construction is shown in dotted outline from the break line L and L in the side wall down to the corresponding bead area in the interest of simplicity of illustration.

In accordance with the present invention, a restrictive 'band 31 is situated peripherally about the outer bias cut nylon cord ply 28 and beneath the tread 19 extending transversely from shoulder 32 on the left to shoulder 33 on the right, the latter being the smooth curve of juncture between the tread stock and the outer rubber ply 35. In the embodiment of FIG. 1, the restrictive reinforcing band 31 extends one complete wrap about the periphery of the tire with the mating edges chamfered and overlapping, although not shown, in a manner similar and customary in the splicing of the tread ply in conventional tire building operations.

The reinforcing band 31 is shown somewhat enlarged in FIG. 3 and, as can be seen, is composed of an elastomeric stock 31 having embedded therein discrete fibers 31b of glass fiber in essentially filament form and bundles or strands 310 of unseparated fibers. The lateral edges 31d and 31e of the restrictive band 31 are desirably feathered for more uniform and unified integral joining with the other tire components during building and vulcanization. The unseparated bundles contained in the restrictive band of elastomeric stock (rubber) can vary in amount from a minimum of about phr. to as much as about 75 phr. Preferably, the range is to 50 phr, and the optimum in reinforcing value is achieved where the amount is about 30 to 35 phr.

Referring now to FIG. 2, the tire 11 is composed of parts bearing the same reference numeral as the tire 11 in FIG. 1. The tire 11 of of FIG. 2 is substantially identical to the tire 11 of FIG. 1 with the exception that the restrictive reinforcing band 31 is situated between bias cut nylon fabric plies 26 and 28. The tire construction employing the reinforcement system as described in either of the embodiments of FIG. 1 or FIG. 2 is capable of being built in accordance with conventional tire building techniques in the tire manufacturing industry. The restrictive band 31 in each case extends transversely from shoulder to shoulder.

The restrictive band 31 including the reinforcing filaments and reinforcing bundles or strands can be produced, in general, by milling, calendering and/ or extrusion; although the latter is less desirable since the distribution of the reinforcing system is not as uniform as with either milling or calendering. The restrictive band may vary in thickness from about 0.020 inch to about 0.125 inch. A thickness of 0.050 is ideal for passenger tire constructions. Tires constructed in accordance with either of the embodiments of FIGS. 1 and 2 were found to minimize flat spotting or thumping due to the nylon cord bias plies propensity to set at the deflected condition on exposure to low temperatures. A number of tires embodying the construction illustrated in FIGS. 1 and 2 were measured and found to be considerably more uniform in diameter at the same inflation pressure varying by as little as inch to /3 inch.

A restrictive reinforcing 'band in accordance with the present invention, but representing a variant embodiment, is illustrated in FIG. 4 and identified by the numeral 41. Like the band construction 31 of FIG. 3, the band 41 contains individual discrete extremely short lengths of glass fiber filaments 41b and also a plurality of unseparated strands, bundles or cord-s 410. The band 41 additionally includes a plurality of mutually parallel cords or strands 42 composed of assembled filaments, either twisted or untwisted. In each case, it is most preferred that the cords, strands or bundles 42 include an impregnation system as described hereinbefore in Examples 47. The band 41 can be manufactured by first drawing a plurality of strand or cord assemblies 71 (FIG. 10) from a plurality of rotatable supply spools 72 held in a creel arrangement 73 as in conventional textile practice, directing the strand or cord assemblies through a comb 74 and thence training the strands under and over an array of rollers arranged to direct the strands into a pool of impregnant 75, thence through a hot air oven 76 and finally through a calender 77 composed of a three roll stack; an elastomeric stock being fed to the top and middle rolls 78 and 79, respectively, while the strands are fed through the middle and bottom rolls 79 and 80, respectively, whereby the strands are combined with elastomeric stock to yield the assembly shown in FIG. 4. Alternatively, a restrictive band construction as shown in FIG. 4 can be formed by hand layup or by a laminating technique wherein two sheets of elastomeric stock have sandwiched therebetween a given number of mutually parallel strands of glass fiber.

It is within the purview of the present invention that the mutually parallel strands 42 may be the same or different fibers. Thus, instead of all being fiber glass, a proportion of the strands may be fiber glass and the balance nylon, rayon, cotton or polyester. It is also within the purview of the present invention to form the cords, strands or cables 42 by employing a mixture of fibers representing three or more different materials, e.g., glass, cotton, rayon, nylon, polyester, etc. Another variant embodiment for the restricting band embodying a reinforcement system in accordance with a further aspect of the present invention is illustrated in FIG. 5 wherein a band 51 (partially broken away) is shown. The band 51 employs discrete, extremely short lengths of glass filaments 51b and a somewhat greater proportion of unseparated cords or strands somewhat greater in length as described hereinbefore and being identified by the reference numeral 510. These are in the form of impregnated strands, bundles or cords. In place of the mutually parallel strands 42 as in the embodiment of FIG. 4, the embodiment of FIG. 5 employs a woven fabric 52 embedded in the elastomeric stock component of the restrictive band 51. The fabric 52 is composed of woof strands 52a and cross or warp strands 52b. The fiber making up these should preferably be different where one is glass. Thus, most preferably, the strands 52a and 52b are not both glass strands. The warp and woof strands 52a and 52b may be strands of glass, nylon, rayon, cotton, polyester (Dacron) and any of the other alternative constructions mentioned hereinbefore. It is within the scope of the present invention to employ two or more of the candidate fibrous strand constructions to weave the fabric 52. As in the case of the mutually parallel strands 52, the fabric may be combined with the restrictive band in any one of the several ways described herein. Preferably, a calendering combination as described previously is employed, although a laminating technique, under certain circumstances, may prove most beneficial.

FIG. 8 illustrates a cord construction 60 in accordance with this invention; said cord employing twisted strands 61, 62, 63, 64, 6-5, 66 and 67. Each of the strands is composed of a plurality of assembled filaments. The cord 60 is shown assembled from a combination of strands of differing materials. Thus, certain of the strands 61-67 maybe glass, a number of them may be cotton and a number of them may be nylon, rayon polyester (Dacron) or the like. It goes without saying, of course, that the cord or cable 60 may be made up of strands 61-67, all of the same filamentary material. Ideally, they are impregnated (see Examples 4-7) in a manner as described (in connection with FIG. 10), particularly where a glass strand .is in assembly therewith. The cord or cable 60 may be employed in fabricating the restrictive :belt or band 41 and, in which case, it would be substituted for the strands 42. Where different fibers, both organic and inorganic, are employed, a considerable versatility and flexibility in combination of properties is imparted to the restrictive band and correspondingly to the tire construction. It will also be appreciated that the cable 60 may be employed as one or the other or both of the strands 52a and 52b in the fabric 52 in the restrictive band 51 in the embodiment of FIG. 5.

In FIGS. 6 and 7, there is disclosed, somewhat schematically, a process and apparatus for retreading a tire in accordance with another embodiment of the present invention. Thus, a tire is mounted on a flanged hub 91, carried rotatably on a shaft 92 mounted on either side in journals 93 and 94 respectively mounted on like supports 94 and 95. A pulley 96 is mounted at one end of the shaft 92 driven by a belt 97 mounted on pulley 98 driven via shaft 99 by a motor 100 connected to a source of electrical power, not shown. The tire mounted, as just discussed, may be rotated at any desired speed. In accordance with the present invention, a supply spool 100a containing a continuous length of previously impregnated glass cord or strand is mounted in spaced parallel relationship with the tire. The shaft 101 of this spool 1000 is parallel to the shaft 92. A continuous length of the strand or cord is drawn from the spool and is fed through a traversing eyelet 1-02 mounted for to and fro travel on a threaded shaft 103, reversably turned by a motor 104 operating via a pair of pulleys 105 and 106 connected by a belt 107. The threading of shaft 103 and governing travel of eyelet 102 arrangement can be selected in order 1 l to give any desired spacing between the length of cord as it is fed peripherally onto the tire, as illustrated by the reference numeral 108 (FIG. 7), yielding a filament wound or spiral wound reinforcing strand as the tire 90 rotates along with the supply spool 1001:. Another supply spool 110 contains a continuous supply of restrictive band stock material, such as that illustrated in either FIGS. 3, 4 or 5. Usually, the construction of FIG. 3, namely, the band 31, will suffice since the spiral wound continuous strand will take the place of the strands 42 in the restrictive band construction 41 of FIG. 4. The breaklines 111 illustrate that a band length 112 can be peripherally wrapped about the previously independently applied spiral strand or cord of glass. Of course, the band construction, as a very thin member, may be continuously wound about the tire contemporaneously with the applied filament wound strand or cord. A further supply spool 120, shown in dotted outline in FIG. 6, represents that two or more strands of glass may be wound about the tire at the same time; care being taken, of course, to employ a separate eyelet traversing rod arrangement, as shown in FIG. 7. Once sufficient continuous glass strands have been spirally wrapped about the carcass, a final wrap of restrictive band 112 may be put about the structure and then the tread stock applied as in conventional retreading operations. The restrictive band alone may be wound about the carcass instead of in combination with the spiral or filament wound cord. Skive knives, although not shown, are usually employed to trim excess rubber from the tire,

whereby molding is easier and dynamic stability of the ultimate retread is improved. It goes without saying that the tread, of course, is first buffed off of the tire 90 to be retreated, and the reference numeral 90 represents a tire from which the tread has been removed by bufiing in a truing and dynamically balanced apparatus.

Although not shown, it is within the purview of the present invention to employ a technique as generally illustrated schematically and described hereinabove in connection with FIGS. 6 and 7 for the original manufacture of tires; in other words, in the tire building process. Thus, it is within the framework of the present invention to adopt the procedure just described to a tire building operation generally similar to that employed in building radial tires. In such a technique, the tire components are built up on a drum or mandrel fitted with bead seal adapters permitting the partially built tire to be pneumatically expanded to a tire configuration whereupon the glass cord can be spirally wound about the crown of the carcass prior to application of the tread strip. Provision can be made for convenient supply rolls of glass cord together with apparatus including a traversing eyelet for feeding the glass cord assembly spirally onto the carcass in the crown region. As in the embodiment shown in FIGS. 6 and 7, we may employ one or more restrictive band members 112. This will tend to further insure isolation and separation of the strands, thereby precluding any interfilament, interstrand or intercord destruction. In any event, when sufiicient wraps of the continuous spiral wound cord have been applied together with an optional cushioning layer of the restrictive band stock material 112, the supply rolls can be pivoted away and the tread stock applied in routine fashion followed by vulcanization in an appropriate mold.

The construction provided by this technique yields a tire possessed of considerable inherent stability just beneath the tread region by reason of the layer of spirally wound glass cords as described. The construction, as just described, finds particular utility in a bias ply cut nylon cord tire, since the continuous plies lend dimensional uniformity insofar as the tire diameter is concerned and additionally prevent growth of the tire due to any inherent thermal deficiency of the nylon cords.

Whether the tire, constructed in accordance with the present invention and the techniques just described, be a new tire manufactured on tire building equipment as just described or whether the tire be a retread tire buffed and constructed as just described, it is found that it is inherently a much more stable tire than known heretofore. Even with the added stability, however, it is found that the harshness of ride is not a necessarily accompanying factor as in the case of wire breaker strip tires of the Michelin type.

Retreading operations employing the technique as just described results not only in a restrictive band in terms of tire size, but also in the creation of a shield which resists penetration by foreign objects frequently found on the air strip as described early in the present application.

The tire shown in FIG. 9 illustrates a variant construction featuring a tire 121 composed of spaced beads 122 and 123 connected by a carcass portion 124 which is a radial cord construction having mutually parallel cords 125 which proceed at an angle of 90 between beads 122 and 123; the 90 being taken with reference to the peripheral center line 126 of the tire. In accordance with the present invention, this radial cord may be nylon, wire or glass cords impregnated as described. The tire includes a tread portion 127 which serves as the ground contacting com onent of the tire. In accordance with the present invention, just beneath the tread portion 127 and extending generally from shoulder 128 to shoulder 129, there is situated two restricting bands or belts 130 and 131; both of which are constructed in accordance with the details of construction described hereinbefore, particularly in connection with FIGS. 3, 4 and 5. The restrictive bands 130 and 131 may be individual separate bands which are positioned peripherally about the tire with chamfered overlapping ends offset one with respect to the other. Alternatively, the segments identified by the reference numerals 130 and 131 may, in fact, represent different plies of a multiple wraparound of an elongate strip or band of a reinforcing restrictive band member composed, for example, of a construction as identified as 31 in FIG. 3, 41 in FIG. 4, or 51 in FIG. 5.

The tire construction embodying the constructional details identified in FIG. 9 is possessed of greater stability dynamically than the conventional radial tire. Additionally, the tire embodying the constructional details of FIG. 9 will not impart to the vehicle, upon which mounted, as harsh a ride as conventional radial tires of the Michelin type employing wire cords in the radial carcass ply and additionally wire reinforced elastomeric stock forming a belt or breaker strip assembly as, for example, noted in the patent to Bourdon, 2,894,555, mentioned earlier herein. It will be appreciated that the radial cords may extend from bead to bead or it may extend from one bead up through one shoulder across the tread area and down into the opposite side wall, while the opposite radial ply proceeds reversely from the opposite head up through the shoulder area and down into the side wall area of the other ply. The just-described configuration represents a two radial ply construction. The overlap in the tread portion tends to increase the stability in the tread region of the tire.

Modifications in constructional details, treatments and technique may be resorted to, and all such obvious equivalents are intended to be included within the scope of the present invention unless the claims expressly delimit the scope otherwise.

We claim:

1. In the method of building a tire wherein cushion plies, carcass plies, bead elements, chafer strips and tread stock are assembled in order, the improvement wherein, after said preformed tire has been inflated and before the tread stock is applied, the following is carried out:

said tire is rotated on its normal axis of rotation, and

an essentially continuous length of a substantially inextensible cord, composed of a plurality of continuous glass fiber filaments assembled together, is wound about the carcass in a peripheral path with respect to the tire while relative transverse move- 13 ment is effected between said tire and said cord to thereby provide a spirally wound cord wrap extending about said periphery and between lateral edges of the ultimate tread region.

2. The method as claimed in claim 1, wherein said inextensible cord is composed of a plurality of continuous glass fiber filaments assembled together.

3. The method as claimed in claim 1, wherein said cord includes additionally filaments selected from the group consisting of cotton, rayon, nylon, polyester and mixtures thereof.

4. The method as claimed in claim .1, wherein said cord components are substantially insulated from each other by an elastomeric compatible coating.

5. In the method of building a tire wherein cushion plies, carcass plies, bead elements, chafer strips and tread stock are assembled in order, the improvement wherein, after the preformed tire has been inflated into generally tire configuration and before the tread stock is applied,

said tire is rotated on its normal axis of rotation,

an essentially continuous length of a substantially inextensible cord, composed of a plurality of continuous glass fiber filaments assembled together, is wound about the carcass in a peripheral path with respect to the tire while relative transverse movement is effected between said tire and said cord to thereby provide a cord wrap extending between lateral edges of the ultimate tread region, and

a separate belt member is applied over said cord-bearing region, said member including a vulcanizable elastomeric stock.

6. The method as claimed in claim 5, wherein said inextensible cord is composed of a plurality of continuous glass fiber filaments assembled together.

7. The method as claimed in claim 5, wherein said elastomeric stock in said belt contains 1 to 10 parts per hundred of rubber of short lengths of discrete glass fibers.

8. The method as claimed in claim 7, wherein said elestomeric stock in said belt contains 5 to 75 parts per hundred of rubber of lengths of glass fiber cord constituting continuous glass fiber strands assembled together, said cord components being substantially insulated from each other by an elastomeric compatible coating.

9. The method as claimed in claim 7, wherein said elastomeric stock in said belt contains 5 to 75 parts per hundred of rubber of lengths of glass fiber cord.

10. The method of retreating a tire which comprises:

rotating a substantially treadless tire on its normal axis of rotation.

feeding a substantially inextensible cord peripherally onto said tire as it rotates, said cord being composed of a plurality of glass fiber elements assembled together and said cord components are substantially insulated from each other by an elastomeric compatible coating,

while simultaneously causing relative transverse movement between said tire and cord, whereby the cord wrap extends in repeated side-by-side spiral disposition about the crown portion of said tire between the shoulders thereof,

applying a vulcanizable tread stock strip over said just-mentioned cord wrap, and

vulcanizing said assembly in a tire mold.

11. The method as claimed in claim 10, wherein a restrictive band or belt of elastomeric stock is applied above and about the carcass and below the tread.

12. The method as claimed in claim 10, wherein said inextensible cord is composed of a plurality of glass fiber filaments assembled together.

13. The method as claimed in claim 12, wherein said cord components are substantially insulated from each other by an elastomeric compatible and insulating coating.

14. The method as claimed in claim '11, wherein said band of elastomeric stock contains 1 to parts per hundred of rubber of discrete short lengths of glass filaments.

15. The method as claimed in claim 14, wherein said elastomeric stock contains 5 to 75 parts per hundred of rubber of continuous lengths of glass fiber cord constituting continuous filaments of glass assembled together, asid cord components being substantially insulated from each other by an elastomeric compatible coating.

16. The method of retreading a tire which comprises:

substantially removing the worn tread portion from the crown portion thereof,

rotating said treadless tire on its normal axis of rotation, feeding a substantially inextensible cord peripherally onto said tire between the shoulders as it rotates,

while simultaneously causing relative transverse movement between said tire and cord, whereby successive cord wraps extend across said crown portion from approximately shoulder to shoulder in slightly spaced to contacting relationship with adjacent wraps, and

applying a vulcanizable tread stock strip over said just-mentioned cord wrap.

17. The method as claimed in claim 16, wherein said cord components are substantially insulated from each other by an elastomeric compatible coating.

18. The method of retreading a tire which comprises:

rotating a substantially treadless tire on its normal axis of rotation, feeding a substantially inextensible cord peripherally onto said tire between the shoulders as it rotates,

while simultaneously causing relative transversemovement between said tire and cord, whereby successive cord wraps extend across the crown portion between the shoulders of the tire in slightly spaced to contacting relationship with adjacent wraps,

applying an occasional strip of vulcanizable elastomeric stock over said spaced cord layer,

applying a vulcanizable tread stock strip over said justmentioned cord wrap, and

vulcanizing said assembly in a mold of the desired contour.

19. The method as claimed in claim 18, wherein said cord is glass cord.

20. The method as claimed in claim 18, wherein a portion of the cord is nylon.

21. The method as claimed in claim 18, wherein a portion of the cord is rayon.

22. The method as claimed in claim 18, wherein a portion of the cord is cotton.

23. The method as claimed in claim 18, wherein a portion of the cord is polyester.

24. In the method of building a tire wherein cushion plies, carcass plies, bead elements, chafer strips and tread stock are assembled in order on a tire building drum, the improvement wherein, before the tread stock is applied, the following is carried out:

at least one band of a vulcanizable elastomeric stock material is applied about the carcass as a restrictive member, said band of stock containing randomly distributed therethrough a plurality of chopped cords formed of gathered together filaments of fiber glass.

25. In the method of building a tire wherein cushion plies, carcass plies, bead elements, chafer strips and tread stock are assembled in order on a tire building drum, the improvement wherein, before the tread stock is applied, the following is carried out:

at least one band of a vulcanizable elastomeric stock material containing a minor amount of reinforcing filamentized discrete glass fibers uniformly dispersed therethrough, and a somewhat greater amount of chopped lengths of fiber glass in cord form, is applied about the carcass as a restrictive member.

26. In the method of building a tire wherein cushion plies, carcass plies, bead elements, chafer strips and tread stock are assembled in order on a tire building drum, the

15 improvement wherein, before the tread stock is applied, the following is carried out:

at least one band containing 1 to 10 parts per hundred of rubber of elastomeric stock of individual glass fibers measuring & to 4 inch in length and 5 to 75 parts per hundred of rubber of elastomeric stock of chopped cord comprising unseparated bundles of plied glass filaments is applied about the carcass as a restrictive member.

27. In the method of building a tire wherein cushion plies, carcass plies, bead elements, chafer strips and tread stock are assembled in order on a tire building drum, the improvement wherein, before the tread stock is applied,

a restrictive band of vulcanizable elastomeric stock is wrapped about the carcass, said band containing a minor amount of filamentized discrete glass fibers uniformly and randomly distributed therethrough and, in addition, a somewhat greater amount of chopped lengths of fiber glass in cord form.

28. The method as claimed in claim 27, wherein said elastomeric stock contains a plurality of mutually parallel cords of glass.

29. The method as claimed in claim 27, wherein said chopped cord constitutes 15 to 50 parts per hundred of rubber and A; to 3 inches in length.

30. The method of producing a reinforcing band for incorporation into a tire construction at the crown portion beneath the tread, said method comprising:

introducing an amount of elastomeric stock onto a roll mixer,

allowing said stock to achieve a workable viscosity while adhering to one of said rolls,

til

introducing 1 to 5 parts per hundred of rubber of stock impregnated cords of glass fibers onto said viscous stock carried by said roll, said cords measuring A2 to 3 inches-in length,

allowing said cords to become worked into said stock while becoming appreciably separated into individual filaments measuring to inch in length,

immediately adding 5 to parts per hundred of rubber of stock impregnated cords of glass into said stock, said cords measuring /a to 3 inches in length,

allowing said cords to mix into said stock without substantial breakup of said cords into filaments, and

removing said stock.

References Cited UNITED STATES PATENTS 2,056,012 9/1936 Madge et a1 152355 2,224,274 12/ 1940 Powers 57153 2,411,659 11/1946 Manning 1561 17 2,546,230 3/1951 Modigliani 161-58 2,906,314 9/1959 Trevaskis 1561 17 X 2,915,102 12/1959 Alexeff et al 152r356 3,245,454 4/ 1966 Lewis 152354 3,245,853 4/1966 Reinhart 156-1 17 3,264,162 8/1966 Holman 156117 X 2,297,354 9/1942 Hawkinson 15696 3,117,047 1/1964 Capistrant et al. 15696 X HAROLD ANSHER, Primary Examiner.

US. Cl. X.R. 

